Chain component and chain

ABSTRACT

Provided are a chain component that has a simple surface treatment structure and can maintain favorable wear resistance over a long time, and a chain that includes this chain component and maintains favorable wear elongation resistance. The chain component of a power transmission chain for industrial use includes a chromium nitride layer containing more than 0 mass % but not more than 55 mass % iron and formed on an outer side of a steel base material.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to chain components such as pins, bushings, link plates, and rollers that constitute power transmission chains for industrial use such as roller chains, and silent chains used, for example, as automobile timing chains, and to a chain including these chain components.

2. Description of the Related Art

It has been known that a chromium nitride film formed on a metal surface enhances wear and corrosion resistance of the metal. Chromium nitride film deposition is thus widely practiced in order to increase the life of machine parts, metal molds, tools, and the like.

Chromium nitride films are commonly formed by physical vapor deposition (PVD) methods such as ion plating or sputtering. In the former process, nitrogen gas is introduced during bombardment of a base material by evaporated and ionized Cr in a vacuum chamber. In the latter process, a high voltage is applied between a target and a substrate to generate a glow discharge so that Ar ions of the plasma hit the target surface to eject Cr atoms to be deposited on the substrate.

One problem with chromium nitride films formed by a PVD method, when used as the surface treatment layer of highly loaded sliding components of a chain, was that the film would easily peel off of the metal base material such as steel, and that it was difficult to make the film adhere to and unite with the surface of the base material such that it would hardly peel off.

PVD also entails occasional formation of droplets on the surface. When there are droplets, the surface roughness increases, and cracks start to form from the droplets and deteriorate wear resistance. Although droplets can be removed by polishing, there will be holes left where droplets were present. These holes enlarge and join each other as load is applied, because of which the wear resistance cannot be improved.

Because of the cracks and deterioration of wear resistance involved in PVD methods, the film thickness could not be made larger to increase the life.

Another problem was that when the material to be processed is porous, it was difficult to form a film on the inner surfaces of the pores.

Pins used in timing chains of car engines are one example of the machine parts mentioned above. Examples of timing chains include roller chains, bushing chains, and silent chains and the like.

A roller chain has rollers fitted on cylindrical bushings, which are press-fit at both ends into bushing holes of a pair of inner plates, while pins fitted in the bushings are press-fit at both ends into pin holes of a pair of outer plates that are arranged on both outer sides of the pair of inner plates. Bushing chains do not have rollers.

For conventional timing chains, the steel base material of the pins would undergo a chromizing treatment, for the purpose of enhancing the wear resistance of the bushings and pins.

However, timing chains used with much deteriorated engine oil inside the car engine room were prone to wear on pins and bushings, because of which their life tended to be short.

Moreover, soot generated in the combustion process of the engine and mixed in the engine oil posed a risk that the friction coefficient of the pins and bushings might increase or the wear might accelerate despite the coating, because lubricating oil containing the soot could penetrate into between the components such as pins and bushings of the timing chain running at high speed under high load, and the soot, which is a hard substance, could damage the coating between the pins and bushings.

Accordingly, a surface treatment that enhances the wear resistance of chains was desired.

Japanese Patent Application Laid-open No. H11-29848 discloses a method of forming chromium nitride films as a solution to the problems entailed in the deposition of chromium nitride films on metal surfaces, i.e., film separation due to heat history and poor adhesion to the base material. After Cr-plating the surface of a metal material, the Cr-plated surface is purified and activated by heating the metal material in a reactive gas containing halogen compounds or halogen, before the nitriding of the Cr-plated surface by heat application in a nitriding atmosphere.

SUMMARY OF THE INVENTION

The method of forming chromium nitride films according to Japanese Patent Application Laid-open No. H11-29848 involves a very complex process, wherein industrial Cr plating is performed to a base material such as steel, followed by special Cr coating such as high corrosion resistant Cr coating without cracks, macroporous Cr coating, and amorphous Cr coating containing 2% to 4% carbon, as well as the pretreatment with halogen, before the nitriding step. As shown in Working Examples 1 to 3 of Japanese Patent Application Laid-open No. H11-29848, the chromium nitride film thus obtained has a Vickers hardness of 1700 to 2000 HV. The difference in hardness between the chromium nitride film and the soft base material is so large that the adhesion is not sufficient for the wear resistance to be maintained over a long time.

If the surface treatment method of Japanese Patent Application Laid-open No. H11-29848 were applied to chain components such as pins and the like of timing chains, there would be problems of complex production process, high production cost, and wear resistance not being maintained favorable over a long time.

The present invention was made in view of such circumstances, and it is an object of the invention to provide a chain component that has a simple surface treatment structure and can maintain favorable wear resistance over a long time, and a chain that includes this chain component and maintains favorable wear elongation resistance.

The chain component according to the present invention is a chain component of a power transmission chain for industrial use and includes a steel base material and a chromium nitride layer formed on an outer side of the steel base material and containing more than 0 mass % but not more than 55 mass % iron.

The chain according to the present invention is formed by a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings, which are alternately interconnected, with the pins being loosely fitted in the bushings. At least one of the pin, bushing, inner plate, and outer plate is the chain component described above.

The chain according to the present invention is formed by a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings each having a roller fitted thereon, which are alternately interconnected, with the pins being loosely fitted in the bushings. At least one of the pin, bushing, inner plate, outer plate, and roller is the chain component described above.

The chain according to the present invention is a chain made up of: a plurality of inner plates having a pair of V-shape link teeth on one end in a short-side direction and a pair of front and rear pin holes, the inner plates being interconnected pivotally by pins inserted in the pin holes and arranged in a width direction of the chain such that one link tooth of each inner plate overlaps the other link tooth of another inner plate adjacent thereto; and guide plates arranged on both outer sides in the width direction with the pins fixedly inserted therethrough. At least one of the pin, inner plate, and guide plate is the chain component described above.

The chain component according to the present invention has the chromium nitride layer formed on the outer side of the steel base material. The chain component has a simple surface treatment structure, and can be readily produced inexpensively with fewer process steps.

Chromium nitride has low friction coefficient and high toughness, so that the chain component famed with the chromium nitride layer exhibits low aggressiveness on counterparts, and hardly suffers damage by minute soot particles or the like having high hardness.

The chromium nitride layer generates low sliding friction heat because of the low friction coefficient. Since chromium nitride has a high oxidation onset temperature and is hardly oxidized even at high temperature, the wear resistance of the chain component is maintained favorably.

Since the chromium nitride layer contains iron, it exhibits favorable adhesion to the steel base material. The iron content is more than 0 mass % but not more than 55 mass %, so that the wear resistance of the chain component is maintained over a long period of time.

The chromium nitride layer exhibits low aggressiveness on counterparts and suffers hardly any damage by minute soot particles or the like having high hardness, so that the degree of freedom in setting the range of clearance distance of sliding parts is increased.

The chain of the present invention has favorable wear elongation resistance because it includes the chain component that exhibits the effects described above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view illustrating part of one example of a roller chain;

FIG. 2 is a perspective view illustrating part of one example of a silent chain;

FIG. 3 is a graph showing a composition distribution of Fe, Cr, and N in a cross section of a pin of Working Example 1 determined by line analysis using an electron probe micro-analyzer (EPMA);

FIG. 4 is a graph showing the results of investigation on the amount of wear on pins and bushings in which the pins are fitted, of a roller chain using the pins of Working Example 1 and of a roller chain using the pins of Comparative Example 1, after a predetermined time of operation of the chain;

FIG. 5 is an optical microscopic image of the surface of the pin according to Working Example 1;

FIG. 6 is an optical microscopic image of the surface of the pin according to Comparative Example 2;

FIG. 7 is a graph showing the relationship between the Fe content in the chromium nitride layer and the wear elongation ratio;

FIG. 8 is a graph showing the relationship between the thickness of the chromium nitride layer and the wear elongation ratio;

FIG. 9A is a view of a bushing chain;

FIG. 9B is a cross-sectional view illustrating clearances between a pin and a bushing of a bushing chain;

FIG. 10 is a graph showing the wear amount plotted against time of pins and bushings when the clearance and surface layer are different; and

FIGS. 11A to 11D are optical microscopic surface images when deteriorated engine oil was used, FIGS. 11A and 11C being those of conventional examples and FIGS. 11B and 11D being those of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A chain component according to the present invention includes a steel base material and a chromium nitride layer famed on an outer side of the steel base material.

The chromium nitride layer contains more than 0 mass % but not more than 55 mass % Fe. The lower limit of the Fe content should preferably be 1 mass %, more preferably 5 mass %, and even more preferably 8 mass %. The upper limit should preferably be 45 mass %, and more preferably 32 mass %.

The layer should preferably have a Fe distribution where the Fe concentration decreases gradually from the surface of the steel base member outward.

Cr and N contents should preferably decrease gradually from the outer side toward the surface of the steel base material.

The chromium nitride layer should preferably contain more than 0 mass % but not more than 55 mass % Fe, 45 mass % or more and 90 mass % or less Cr, and 5 mass % or more and 25 mass % or less N, based on 100 mass % of a total amount.

The lower limit of the Fe content should preferably be 1 mass %, more preferably 5 mass %, and even more preferably 8 mass %. The upper limit should preferably be 45 mass %, and more preferably 32 mass %.

The lower limit of the Cr content should preferably be 48 mass %, and more preferably 51 mass %. The upper limit should preferably be 77 mass %, and more preferably 67 mass %.

The lower limit of the N content should preferably be 9 mass %, and more preferably 13 mass %.

The values of Fe content are those determined by qualitative/quantitative analysis using an EPMA. The values of Cr and N contents are those determined by qualitative/quantitative analysis using an EPMA and corrected in consideration of the values of reference samples of chromium nitride.

The chromium nitride layer should preferably have a thickness of 2 μm or more and 30 μm or less. In this range, the surface roughness is small, cracks hardly form, and wear resistance is favorable, which leads to favorable wear elongation resistance of a chain having the chain component assembled therein.

An intermediate layer may be provided between the chromium nitride layer and the steel base material in order to increase the adhesion of the chromium nitride layer to the steel base material.

Examples of the intermediate layer include Cr, CrB, CrB₂, CrC, Cr₂N, Cr₂O₃, CrSi₂, CrNi, CrB—O, CrB₂—O, (V,Cr)C, (Cr,Zr)N, CrBN, CrB₂+Ni, (Cr, Mn)C, (Cr, Mo)N, (V, Cr)B, (Cr, Fe)C, (Cr, W)N, (Cr, Mn)B, (Cr, Co)C, (Cr, Cu)N, (Cr, Fe)B, (Cr, Ni)C, (Cr, V)N, (Cr,Co)B, (Cr,Cu)C, (Cr,Ni)B, (Cr,Zn)C, (Cr,Cu)B, (Cr,Zr)C, (Cr,Zn)B, (Cr,Nb)C, (Cr,Zr)B, (Cr,Mo)C, (Cr,Nb)B, (Cr,Hf)C, (Cr,Mo)B, (Cr,Ta)C, (Cr,Hf)B, (Cr,W)C, (Cr,Ta)B, (Cr,W)B, and the like.

The chromium nitride layer on the chain component according to the present invention is formed on the outer side of the steel base material in the following manner: The steel base material and a treatment agent containing Cr powder, aluminum oxide (hereinafter referred to as alumina), and ammonia halide are placed in a heating furnace, and the temperature of the heating furnace is raised to a target value. After the temperature is kept for a predetermined time, the heating furnace is slowly cooled down. The treatment agent can contain a compound, which the element contained in the intermediate layer mentioned above originates from.

Hereinafter, a chain component according to the present invention will be described, wherein the component is pins of a roller chain used as a timing chain or the like of a car engine.

FIG. 1 is a perspective view illustrating part of one example of a roller chain 1.

The roller chain 1 has bushings 3 press-fit at both ends into bushing holes 2 a of a pair of inner plates 2, and pins 6 fitted in the bushings 3 and press-fit at both ends into pin holes 5 a of a pair of outer plates 5 that are arranged on both outer sides of the pair of inner plates 2. Rollers 4 are fitted on the bushings 3.

The chromium nitride layer described above is provided on the outer side of the pins 6.

Hereinafter, the method of producing the pins 6 as one example of chain component according to the present invention will be described.

Wire rods of carbon steel, chromium-molybdenum steel (SCM), or high-carbon chromium bearing steel (SUJ) and the like are used as the steel base material of the pins 6.

The chromium nitride layer is formed on the surface of the steel base material of the pins 6 by diffusion coating of Cr and N.

For the Cr diffusion coating process, the process referred to as “powder pack” method can be adopted.

More specifically, the pin 6 and a treatment agent containing Cr powder, alumina, and ammonium halide are packed in an alumina boat, for example, which is then placed in a heating furnace such as an electric furnace, for example. The treatment agent should preferably contain 60 to 67 mass % Cr powder, 30 to 37 mass % alumina, and 0.2 to 3 mass % ammonium halide, based on 100 mass % of a total amount.

Examples of ammonium halide include ammonium chloride, ammonium bromide, ammonium iodide, ammonium fluoride and the like. One type or two or more types of ammonium halide are selected in accordance with the target layer structure.

The atmosphere is replaced with an inert gas such as Ar or N₂ before raising the temperature.

The temperature is then raised to a predetermined level.

During the heating, a preset flow amount of NH₃ and/or N₂ may be introduced in accordance with the thickness, film configuration, and total film thickness of the target chromium nitride layer.

The furnace is cooled down after keeping the temperature for a predetermined period of time.

If the target film has not been famed yet, the furnace is again heated to the predetermined temperature while introducing NH₃ and/or N₂, and cooled down after holding the temperature for a preset time.

The composition ratio of the treatment agent, treatment temperature, and holding time are determined in consideration of the composition of the steel base material, and the thickness, film configuration, and total film thickness or the like of the target chromium nitride layer.

Nitridation of the surface or CrC layer of the steel base material is one example of method of foaming a chromium nitride layer.

According to this method of forming a chromium nitride layer, a chromium nitride layer can be formed on the outer side of the steel base material easily and inexpensively with a few process steps. Cr, C, and Fe have concentration gradients, and favorable adhesion between the chromium nitride layer and the steel base material is achieved.

The chain component obtained by the production method described above has favorable wear resistance since it has the chromium nitride layer on the outer side, which has a high oxidation onset temperature and is hardly oxidized even at high temperature. Also, favorable wear elongation resistance is maintained for a long period of time because of the favorable adhesion between the chromium nitride layer and the steel base material.

While one example has been described above wherein the chromium nitride layer is famed on the pin 6, the target is not limited to the pin. The chromium nitride layer may be formed on the surface of at least one of the inner plate 2, bushing 3, roller 4, and outer plate 5.

The chain 1 having the chain component according to the present invention maintains favorable wear elongation resistance over a long period of time.

The chain according to the present invention may be a bushing chain that does not have rollers.

The chain according to the present invention may be a silent chain.

FIG. 2 is a perspective view illustrating part of one example of a silent chain 10.

The silent chain 10 is made up of a plurality of inner plates 11 having a pair of V-shape link teeth 11 a on one end in the short-side direction and guide plates 13 arranged on both outer sides in a width direction of the silent chain 10 with pins fixedly inserted therethrough. The inner plates 11 are interconnected pivotally by pins 12 inserted in pin holes and arranged in the width direction such that one link tooth 11 a of each inner plate 11 overlaps the other link tooth 11 a of another inner plate 11 adjacent thereto.

The silent chain 10 includes the chromium nitride layer on the surface of at least one of the chain components including the inner plates 11, pins 12, and guide plates 13.

EXAMPLES

The present invention will be described below in more specific terms based on working examples.

Working Example 1

An SUJ2 wire rod was used as the processed material of Working Example 1, which was cut to a predetermined length and ground, to obtain a pin 6 material, as the steel base material.

A treatment agent containing Cr powder, alumina, and NH₄Cl each in an amount within the ranges specified above, was set in an alumina boat with the pin 6, and the alumina boat was placed in a heating furnace. After replacement with an inert gas, the furnace was heated to the preset temperature while introducing a suitable flow amount of an additive gas (NH₃ and N₂). The temperature was held for a while to form a chromium nitride layer on the outer side of the pin 6. The heater power source was turned off after that and the furnace was cooled down slowly.

A pin 6 with a chromium nitride layer formed on the outer side of the steel base material was thus obtained.

The chromium nitride layer contained 13 mass % Fe, 74 mass % Cr, and 13 mass % N, and had a thickness of 13 μm.

FIG. 3 is a graph showing a composition distribution of Fe, Cr, and N in a cross section of the pin 6 of Working Example 1 determined by line analysis using an EPMA. The horizontal axis represents the length in the thickness direction, and the vertical axis represents the detection intensity of each component.

The measurement conditions were as follows.

-   -   Acceleration voltage: 15 kV     -   Sample current: 50 nA     -   Beam diameter: 1 μm

FIG. 3 indicates that the Fe content gradually increases, while the Cr and N contents gradually decrease, from the outer side toward the surface of the base material of the pin 6.

The above results confirmed that a chromium nitride layer was famed on the outer side of the steel base material wherein Cr and N diffused in part on the surface side of the pin 6 material. Cr and N have concentration gradients because they diffused. The layer also has a Fe concentration distribution decreasing gradually from the surface of the steel base material toward the outer side. Because of these concentration gradients of Fe, Cr, and N, it can be seen that there is favorable adhesion between the base material of the pin 6 and the chromium nitride layer.

Comparative Example 1

Pins as Comparative Example 1 were obtained by a conventional powder pack method, wherein a 15 μm thickness CrC layer was formed on a steel base material.

Comparative Example 2

Pins as Comparative Example 2 were obtained by a conventional PVD method, wherein a 6 μm thickness chromium nitride layer was famed on a steel base material.

Roller chains were assembled using the pins 6 of Working Example 1, the pins of Comparative Example 1, and the pins of Comparative Example 2.

The wear elongation resistance of each roller chain was evaluated.

A car was actually driven 5000 km, 10,000 km, and 15,000 km in town using an SAE 5W-30 engine oil, and the deteriorated engine oil was collected after each drive.

Using each engine oil, the roller chains each including the pins of Working Example 1, Comparative Example 1, and Comparative Example 2 were tested under severe conditions where they were run at high speed for 100 hours. The results are shown in Table 1. Table 1 indicates the wear elongation in percentage (wear elongation ratio) of Working Example 1 and Comparative Example 2 in relation to that of the roller chain of Comparative Example 1 as 100.

TABLE 1 (%) Driving Working Comparative Comparative distance (km) Example 1 Example 1 Example 2 5000 80 100 118 10,000 70 100 146 15,000 63 100 182

Table 1 indicates that Working Example 1 had better wear elongation resistance than Comparative Example 1, which had better wear elongation resistance than Comparative Example 2. Namely, it can be seen that the roller chain 1 of Working Example 1, which has a chromium nitride layer containing more than 0 mass % but not more than 55 mass % Fe on the outer side of the steel base material, has favorable wear elongation resistance. With an increase in the driving distance (as the engine oil is more deteriorated), the effect of improving the wear elongation resistance by the chromium nitride layer is increased.

FIG. 4 is a graph showing the results of investigation on the amount of wear on pins and bushings in which the pins are fitted, of a roller chain using the pins 6 of Working Example 1 and of a roller chain using the pins of Comparative Example 1, after a predetermined time of operation of the chain.

FIG. 4 shows that the amount of wear on pins and bushings is reduced when the roller chain having the pins 6 of Working Example 1 is used, as compared to when the roller chain having pins of Comparative Example 1 is used. The wear on bushings is reduced particularly largely. This is because the chromium nitride layer on the pins 6 of Working Example 1 exhibits low aggressiveness on the sliding counterparts (bushings).

FIG. 5 is an optical microscopic image showing the surface of the pin 6 of Working Example 1. FIG. 6 is an optical microscopic image showing the surface of the pin of Comparative Example 2.

While no droplets are present on the surface of the pin 6 of Working Example 1 as shown in FIG. 5, there are a large number of droplets on the surface of the pin of Comparative Example 2. It can be seen that the pin of Comparative Example 2 has a larger surface roughness and will have poorer wear resistance because of cracks that will start from the droplets.

Next, the results of the wear elongation resistance evaluation test will be described. The test was conducted using deteriorated engine oil, with varying Fe content in the chromium nitride layer on the roller chain.

Similarly to Working Example 1, pins 6 of Working Examples 2 to 6 and pins of Comparative Example 3 were fabricated, each with the element composition as specified in Table 2 below. Table 2 also shows Working Example 1 and Comparative Example 1.

The values of Fe content, of the elements in Table 2, are those determined by qualitative/quantitative analysis using an EPMA. The values of Cr and N contents are those determined by qualitative/quantitative analysis using an EPMA and corrected in consideration of the values of reference samples of chromium nitride.

TABLE 2 (%) Working Working Working Working Working Working Comparative Comparative Example 2 Example 3 Example 4 Example 1 Example 5 Example 6 Example 1 Example 3 Cr 90 77 67 74 51 45 30 N 9 18 25 13 17 5 15 Fe 1 5 8 13 32 55 60 Total 100 100 100 100 100 105 105 Wear 80 67 60 59 60 98 100 122 elongation ratio

A car was actually driven 10,000 km in town using an SAE 0W-20 engine oil, and the deteriorated engine oil was collected and used in the test.

Using this engine oil, the roller chains each including the pins of Working Examples 1 to 6, Comparative Example 1, and Comparative Example 3 were tested under severe conditions where they were run at high speed for 150 hours. The results are shown in Table 2. Table 2 indicates the wear elongation in percentage (wear elongation ratio) of various working examples and Comparative Example 3 in relation to that of the roller chain of Comparative Example 1 as 100.

FIG. 7 is a graph showing the relationship between the Fe content in the chromium nitride layer and the wear elongation ratio. The horizontal axis represents the Fe content (mass %), and the vertical axis represents the wear elongation ratio (%).

Table 2 and FIG. 7 show that the roller chains 1 of various working examples that have a chromium nitride layer containing more than 0 mass % but not more than 55 mass % Fe have favorable wear elongation resistance.

The lower limit of the Fe content should preferably be 1 mass %, more preferably 5 mass %, and even more preferably 8 mass %. The upper limit should preferably be 45 mass %, and more preferably 32 mass %.

The lower limit of the Cr content should preferably be 48 mass %, and more preferably 51 mass %. The upper limit should preferably be 77 mass %, and more preferably 67 mass %.

The lower limit of the N content should preferably be 9 mass %, and more preferably 13 mass %.

The results of the wear elongation resistance evaluation test, which was conducted using deteriorated engine oil, with varying thickness of the chromium nitride layer on the roller chain, will be described.

A car was actually driven 10,000 km in town using an SAE 0W-30 engine oil, and the deteriorated engine oil was collected and used in the test.

Using this engine oil, the roller chains each including the pins of various working examples with various different thicknesses of the chromium nitride layer were tested under severe conditions where they were run at high speed for 180 hours.

FIG. 8 is a graph showing the relationship between the thickness of the chromium nitride layer and the wear elongation ratio. The horizontal axis represents the layer thickness (μm), and the vertical axis represents the percentage of wear elongation resistance (%) in relation to that of the roller chain of Comparative Example 1 as 100.

FIG. 8 shows that the wear elongation resistance is favorable when the thickness of the chromium nitride layer is 2 μm or more and 30 μm or less. When the layer thickness is more than 30 μm, cracks form and deteriorate the wear elongation resistance.

As demonstrated above, it was confirmed that the chromium nitride layer of the pins 6 according to working examples of the present invention had no droplets so that it would hardly peel off, the layer would exhibit low aggressiveness on the counterparts, and since the layer thickness could be in the range of 2 μm to 30 μm, the roller chain 1 would have favorable wear elongation resistance that would be maintained favorable over a long period of time.

Next, the results of the test conducted with the use of deteriorated engine oil on the bushing chain 20 shown in FIGS. 9A and 9B will be described.

Generally, the clearance distance CL between the pin 6 and the inner circumference of the bushing 3 is designed small for better wear resistance, to reduce the surface pressure on bearing parts when tension is applied.

However, too small a clearance distance CL leads to poorer twistability and flexibility of the entire chain and poorer assemblability to the engine, as well as to a lower strength because of the load applied by the chain itself.

Too small a clearance distance CL also allows soot or the like in the engine oil to accumulate more readily. The friction coefficient will increase by the damage caused by the soot or the like on the surfaces of the pins and inner circumference of the bushings, which can cause heat generation and an increase in resistance and wear.

Accordingly, the clearance distance CL is strictly designed in a very small range in accordance with the purpose and environment of use in consideration of the relationship between reduction of the surface pressure on bearing parts when tension is applied and other influences.

According to the present invention, by the application of the low-friction and high-toughness chromium nitride layer on the surface, the clearance distance CL can be increased, which increases the surface pressure on the bearing parts, without loss of wear resistance.

Since the chromium nitride layer exhibits low aggressiveness on counterparts and suffers little damage by minute soot particles having high hardness, the clearance distance CL can be decreased to allow soot or the like to more readily accumulate with less possibility of damage by the soot on the surfaces of the pins and inner circumference of the bushings, which in turn reduces the possibilities of heat generation and increased resistance or wear caused by an increased friction coefficient.

This increases the degree of freedom in setting the clearance distance CL and thus makes it possible to flexibly deal with various purposes and changes in the environment of use.

More specifically, it was confirmed that the chain could be used without problems with the clearance distance CL between the pins 6 and bushings 3 being in the range of 30 μm to 120 μm.

It was also confirmed that the chain could be used without problems when 60≥CL/N≥2.8 where N is the thickness of the chromium nitride layer, and that the clearance distance CL could be made sufficiently large even if the layer thickness was small.

FIG. 10 shows changes in wear elongation plotted against time of a chain with a conventional chromizing treatment on the surface of the pins 6 and the chain with the chromium nitride layer of the present invention when deteriorated engine oil was used.

The elongation of the chain with the chromium nitride layer of the present invention was doubtless reduced irrespective of the clearance distance CL.

Even when the clearance distance CL was large, elongation of the chain with the chromium nitride layer of the present invention was more or less the same as that of the chain with the conventional chromizing treatment when the clearance distance CL was small, which confirmed that the degree of freedom in setting the clearance distance CL was increased.

FIGS. 11A to 11D show images of the surface conditions of the pin with the conventional chromizing treatment and the pin with the chromium nitride layer of the present invention.

FIG. 11A and FIG. 11B show scratched surface conditions of the pin with the conventional chromizing treatment and the pin with the chromium nitride layer of the present invention when deteriorated engine oil was used. FIG. 11C and FIG. 11D show the conditions of surface with impression of the pin with the conventional chromizing treatment and the pin with the chromium nitride layer of the present invention when a Vickers hardness test was conducted.

As can be seen from the scratch conditions in FIG. 11A and FIG. 11B, while the pin with the conventional chromizing treatment had many scratches, the pin with the chromium nitride layer of the present invention had hardly any scratch because of the low friction coefficient and high toughness.

As can be seen from FIG. 11C and FIG. 11D, while the pin with the conventional chromizing treatment had cracks around the impression, the pin with the chromium nitride layer of the present invention showed no cracks because of the high toughness.

As described above, the chain component according to the present invention is a chain component of a power transmission chain for industrial use and characterized in that it includes a steel base material and a chromium nitride layer famed on an outer side of the steel base material and containing more than 0 mass % but not more than 55 mass % iron.

According to the present invention, the chromium nitride layer is formed on the outer side of the steel base material. The chain component has a simple surface treatment structure, and can be readily produced inexpensively with fewer process steps.

Chromium nitride has low friction coefficient, so that the chain component no fled with the chromium nitride layer exhibits low aggressiveness on counterparts. The chromium nitride layer generates low sliding friction heat. Moreover, chromium nitride has a high oxidation onset temperature and is hardly oxidized even at high temperature, so that the wear resistance of the chain component is maintained favorably.

Since the chromium nitride layer contains iron, it exhibits favorable adhesion to the steel base material. Also, since the iron content is more than 0 mass % but not more than 55 mass %, the wear resistance of the chain component is maintained over a long period of time.

The chain component according to the present invention is further characterized in that the chromium nitride layer has an iron concentration distribution decreasing gradually from a surface of the steel base material outward.

According to the present invention, the adhesion to the steel base material is even more favorable.

The chain component according to the present invention is further characterized in that the chromium nitride layer has a chromium and nitrogen concentration distribution decreasing gradually from an outer side toward the surface of the steel base material.

According to the present invention, the adhesion to the steel base material is even more favorable.

The chain component according to the present invention is further characterized in that the iron content is 1 mass % or more and 45 mass % or less.

According to the present invention, the wear resistance is even better.

The chain component according to the present invention is further characterized in that it contains more than 0 mass % but not more than 55 mass % iron, 45 mass % or more and 90 mass % or less chromium, and 5 mass % or more and 25 mass % or less nitrogen, based on 100 mass % of a total amount.

According to the present invention, the wear resistance is maintained more favorably, and the adhesion to the steel base material is even better.

The chain component according to the present invention is further characterized in that the chromium nitride layer has a thickness of 2 μm or more and 30 μm or less.

According to the present invention, the surface roughness is small, cracks hardly form, and wear resistance is favorable.

The chain according to the present invention is formed by a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings, which are alternately interconnected, with the pins being loosely fitted in the bushings, and characterized in that at least one of the pin, bushing, inner plate, and outer plate is one of the chain components described above.

The bushing chain of the present invention has favorable wear elongation resistance.

The chain according to the present invention is formed by a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings each having a roller fitted thereon, which are alternately interconnected, with the pins being loosely fitted in the bushings, and characterized in that at least one of the pin, bushing, inner plate, outer plate, and roller is one of the chain components described above.

The roller chain of the present invention has favorable wear elongation resistance.

The chain according to the present invention is further characterized in that at least one of the pin and bushing is one of the chain components described above and that the clearance distance between the pin and the bushing is in the range of 30 μm to 120 μm.

The chain of the present invention has favorable wear elongation resistance and can flexibly deal with various purposes and changes in the environment of use.

The chain according to the present invention is a chain made up of a plurality of inner plates having a pair of V-shape link teeth on one end in a short-side direction, the inner plates being interconnected pivotally by pins inserted in the pin holes and arranged in a width direction of the chain such that one link tooth of each inner plate overlaps the other link tooth of another inner plate adjacent thereto, and guide plates arranged on both outer sides in the width direction with the pins fixedly inserted therethrough, and characterized in that at least one of the pin, inner plate, and guide plate is one of the chain components described above.

The silent chain of the present invention has favorable wear elongation resistance.

The chain according to the present invention is further characterized in that at least one of the pin and inner plate is one of the chain components described above and that the clearance distance between the pin and the inner plate is in the range of 30 μm to 120 μm.

The chain of the present invention has favorable wear elongation resistance and can flexibly deal with various purposes and changes in the environment of use.

It should be interpreted that the embodiments disclosed herein are given for illustrative and not restrictive purposes in all features. The scope of the present invention shall not be determined by the description above and is intended to include contents equivalent to the claims and all changes made within the scope of the claims.

For example, the chain component of the present invention is not limited to components of the roller chain, bushing chain, and silent chain described above. Also, the chain component can be applied to components of power transmission chains for industrial use other than timing chains. 

1. A chain component of a power transmission chain for industrial use, comprising: a steel base material; and a chromium nitride layer formed on an outer side of the steel base material and containing more than 0 mass % but not more than 55 mass % iron.
 2. The chain component according to claim 1, wherein the chromium nitride layer has an iron concentration distribution decreasing gradually from a surface of the steel base material outward.
 3. The chain component according to claim 1, wherein the chromium nitride layer has a chromium and nitrogen concentration distribution decreasing gradually from an outer side toward a surface of the steel base material.
 4. The chain component according to claim 1, wherein the iron is contained in a mass % of 1 or more and 45 or less.
 5. The chain component according to claim 1, containing more than 0 mass % but not more than 55 mass % iron, 45 mass % or more and 90 mass % or less chromium, and 5 mass % or more and 25 mass % or less nitrogen, based on 100 mass % of a total amount.
 6. The chain component according to claim 1, wherein the chromium nitride layer has a thickness of 2 μm or more and 30 μm or less.
 7. A chain comprising a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings, which are alternately interconnected, with the pins being loosely fitted in the bushings, at least one of the pin, the bushing, the inner plate, and the outer plate being the chain component according to claim
 1. 8. A chain comprising a plurality of pairs of outer plates each connected by two pins and a plurality of pairs of inner plates each connected by two bushings each having a roller fitted thereon, which are alternately interconnected, with the pins being loosely fitted in the bushings, at least one of the pin, the bushing, the inner plate, the outer plate, and the roller being the chain component according to claim
 1. 9. The chain according to claim 7, wherein at least one of the pin and the bushing is the chain component, and a clearance distance between the pin and the bushing is 30 μm to 120 μm.
 10. A chain comprising: a plurality of inner plates having a pair of V-shape link teeth on one end in a short-side direction and a pair of front and rear pin holes, the inner plates being interconnected pivotally by pins inserted in the pin holes and arranged in a width direction of the chain such that one link tooth of each inner plate overlaps the other link tooth of another inner plate adjacent thereto; and guide plates arranged on both outer sides in the width direction, with the pins being fixedly inserted therethrough, at least one of the pin, the inner plate, and the guide plate being the chain component according to claim
 1. 11. The chain according to claim 10, wherein at least one of the pin and the inner plate is the chain component, and a clearance distance between the pins and pin holes in inner plates in sliding contact with the pins is 30 μm to 120 μm. 